G protein coupled receptors (GPCR) form the largest and most diversified family of cell-surface receptors responsible for signal transduction inside the cells. Extensive research over the last thirty years have led to the identification of multiple proteins interacting with GPCRs and controlling the signalisation, desensitization, internalization and degradation of these important pharmaceutical targets. In contrast to the processes regulating GPCR activity at the plasma membrane, the molecular mechanisms controlling GPCR biogenesis in the endoplasmic reticulum (ER) and their transport to the cell-surface are poorly characterized. The identification of the proteins regulating GPCR maturation is essential in order to understand how receptors are expressed at the plasma membrane.
A proteomic screen based on bioluminescence resonance energy transfer (BRET), which allows for the detection of protein-protein interaction in living cells, led to the identification of several potential novel GPCR interactors localized in the secretory pathway. Since the cellular compartments where these proteins are localized are responsible for the synthesis, proper folding and transport to the plasma membrane of the receptors, it is highly probable that they are involve in regulating GPCR cell-surface expression.
The characterization of the human cornichon homolog 4 (CNIH4), a novel GPCR interactor identified in the screen, showed that this protein localized in the early secretory pathway (ER and ERGIC), selectively interacts with GPCRs. Knockdown of the endogenous expression of this previously uncharacterized protein led to a decrease in the cell-surface expression of a receptor indicating that CNIH4 has a positive function in the ER export of GPCR. Supporting this, over-expression of CNIH4 at low levels increased the maturation of a mutant receptor normally retained in the ER. Moreover, CNIH4 interacts with Sec23, a component of the inner coat of COPII vesicles which transport proteins from the ER to the Golgi apparatus, suggesting that CNIH4 could recruit GPCRs in these vesicles.
CNIH4 over-expression at very high levels also resulted in the intracellular trapping of the receptors. This dominant negative effet could be caused by the titration of another component of the GPCR export process. Another study showed that the transmembrane protein 9 (TMEM9), a novel GPCR interactor also identified in the screen, selectively interacts with GPCRs and CNIH4. Over-expression of this protein of previously unknown function restored normal receptor trafficking in presence of over-expressed CNIH4. Morevover, co-expression of TMEM9 potentialized CNIH4 ability to increase the maturation of a mutant receptor normally retained in the ER, suggesting that these proteins form a complex regulating GPCR maturation.
During this thesis, novel GPCR interacting proteins controlling receptor expression at the plasma membrane were identified, allowing for a better understanding of the mechanisms controlling receptor trafficking from the ER to the cell-surface.